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In the following example, if I have multiple types in the list it compiles ok, but if I have one element, it chooses a different type which is no longer assignable.

// compiles fine
List<Class<? extends Reference>> list = Arrays.asList(SoftReference.class, WeakReference.class);
// but take an element away and it no longer compiles.
List<Class<? extends Reference>> list2 = Arrays.asList(WeakReference.class);
// without giving the specific type desired.
List<Class<? extends Reference>> list3 = Arrays.<Class<? extends Reference>>asList(WeakReference.class);

I am sure there is a logical explaination for this, but it escapes me.

    Error:Error:line (30)error: incompatible types
required: List<Class<? extends Reference>>
found:    List<Class<WeakReference>>

Why does having two elements compile but one element does not?

BTW: It is hard to find a simple example, if you try

List<Class<? extends List>> list = Arrays.asList(ArrayList.class, LinkedList.class);

    Error:Error:line (28)error: incompatible types
required: List<Class<? extends List>>
found:    List<Class<? extends INT#1>>
where INT#1 is an intersection type:
INT#1 extends AbstractList,Cloneable,Serializable

This doesn't compile either (it won't even parse)

List<Class<? extends AbstractList & Cloneable & Serializable>> list = Arrays.asList(ArrayList.class, LinkedList.class);

Error:Error:line (30)error: > expected
Error:Error:line (30)error: ';' expected

but this compiles fine

static abstract class MyList<T> implements List<T> { }
List<Class<? extends List>> list = 
        Arrays.asList(ArrayList.class, LinkedList.class, MyList.class);
List<Class<? extends List>> list = 
        Arrays.<Class<? extends List>>asList(ArrayList.class, LinkedList.class);

EDIT: Based on Marko's example. In these four example, one doesn't compile, the rest produce the same list of the same type.

List<Class<? extends Reference>> list = new ArrayList<>();
list.add(SoftReference.class);
list.add(WeakReference.class);
list.add(PhantomReference.class);

List<Class<? extends Reference>> list = new ArrayList<>(
     Arrays.asList(SoftReference.class));
list.add(WeakReference.class);
list.add(PhantomReference.class);

List<Class<? extends Reference>> list = new ArrayList<>(
     Arrays.asList(SoftReference.class, WeakReference.class));
list.add(PhantomReference.class);

List<Class<? extends Reference>> list = new ArrayList<>(
     Arrays.asList(SoftReference.class, WeakReference.class, PhantomReference.class));
share|improve this question
    
I think that the compiler in jdk < 7 asks for the two parts of the statement to have the same declaration. also not 100% sure that this is what causing the problem!! –  mamdouh alramadan Dec 30 '12 at 15:08
    
I am using Java 7 update 9. –  Peter Lawrey Dec 30 '12 at 15:11
    
then as i think you either add the same declaration in both sides of the statement or not to declare it at all in the second part. –  mamdouh alramadan Dec 30 '12 at 15:14
    
@mamdouhalramadan I agree that is a work around as I have found. I am curious to know why the rules for implicit casting appear to be different in differnt situations –  Peter Lawrey Dec 30 '12 at 15:16
1  
All the cases make sense to me, I still don't see the tension you want to create between the working and non-working cases. Class<WeakReference> is-not-a Class<? extends WeakReference> so naturally you can't assign. The example does point out the weakness of the generic type system, though. –  Marko Topolnik Dec 30 '12 at 16:17

4 Answers 4

up vote 10 down vote accepted

Interesting problem. I think that what's going on is this. When you have two elements like you show, the return type from asList is most specific type of all the arguments, which in your first example is List<Reference>. This is assignment-compatible with List<? extends Reference>. When you have a single argument, the return type is the specific type of the argument, which is not assignment-compatible because generics are not covariant.

share|improve this answer
    
By "not conformant" do you mean they don't follow the Spec? –  Peter Lawrey Dec 30 '12 at 15:11
    
@PeterLawrey - Oops--wrong word. I meant "covariant". Updated the answer. –  Ted Hopp Dec 30 '12 at 15:12
    
It appears to me that the rules for implicit casting are different in different situations. There must be some logic which says it's ok to cast one way with asList which it cannot do with an assignment. –  Peter Lawrey Dec 30 '12 at 15:15
3  
@PeterLawrey - I phrased that wrong. The rules are the same, but the cases are different, so different aspects of the rules apply. Each actual argument is being assigned to a parameter that is the intersection type of all the actual parameters. Pretty much by definition of the intersection type, this cannot cause a problem. The assignment statement, on the other hand, assigns the intersection type to a generic type specified by your code. That's when there can be a problem (in this case because generic types are not covariant). –  Ted Hopp Dec 30 '12 at 17:07
1  
This explanation is wrong on several counts: first of all, List<WeakReference> is assignment-compatible with List<? extends Reference>. Second, the question is not about these types, but about List<Class<? extends Reference>> -- and only there the trouble begins, because now there's no wildcard capture happening. Also take note that generic types would be broken if they were covariant, so it's not much of an explanation. –  Marko Topolnik Dec 30 '12 at 18:17

Consider

    // ok
    List<Object> list3 = Arrays.asList(new Object(), new String());
    // fail
    List<Object> list4 = Arrays.asList(new String());

The 2nd example tries to assigne a List<String> to a List<Object>, which fails.

The 2nd example could work, if javac looks at the surrounding context, takes into account the target type, and deduce that T=Object would work here. Java 8 will probably do that (I'm not sure)

Only in one situation, javac (of java 5) will use contextual info for type inference, see http://docs.oracle.com/javase/specs/jls/se7/html/jls-15.html#jls-15.12.2.8

We can take advantage of that to make a workaround

public static <R, T extends R> List<R> toList(T... elements)
{
    return Arrays.asList((R[])elements);
}

Now they can be compiled:

    List<Object> list4 = toList(new String());

    List<Class<? extends Reference>> list = toList(SoftReference.class, WeakReference.class);

    List<Class<? extends Reference>> list2 = toList(WeakReference.class);

This is because R cannot be inferred from argument types, and the method result is in an assignment context, so javac tries to infer R by the target type.

This works in assignment, or in a return statement

List<Class<? extends Reference>> foo()
{
    return toList(WeakReference.class);  // "subject to assignment conversion"
}

It won't work otherwise

void bar(List<Class<? extends Reference>> list){...}

bar( toList(WeakReference.class) ); // fail; R not inferred
share|improve this answer
2  
+1, this is the correct answer. The key is in the first line of JLS §15.12.2.8: "If any of the method's type arguments were not inferred from the types of the actual arguments, they are now inferred as follows...." Since the type of the returned list is inferred from the actual arguments in the case of Arrays.asList(), the rules for contextual inference do not apply. –  Daniel Pryden Dec 31 '12 at 6:12
    
You'll still need to add @SuppressWarnings ("unchecked") to the toList method. Without it I get an Unchecked generics array creation for varargs parameter warning. –  Aaron Mahan May 22 at 14:31
    
List <Object> list4 = toList(new String()); doesn't compile (incompatible types). Please fix your answer. –  Aaron Mahan May 22 at 15:30

This is interesting:

where INT#1 is an intersection type:
INT#1 extends AbstractList,Cloneable,Serializable

Maybe that is the cause for (some of the) issues?

The intersection type of the elements may not be uniquely determined. When you declare your own list MyList<T> implements List<T>, the intersection type of the array is determined as List<T>.

When using Arrays.<Class<? extends List>>asList(ArrayList.class, LinkedList.class); the 'intersection' type is explicitly stated (as List) and does not need to be inferred by the compiler.

Besides that, I believe what Ted Hopp said is correct for the other case.

EDIT:

The difference between

List<Class<? extends Reference>> list2 = Arrays.asList(WeakReference.class);

and

List<Class<? extends Reference>> list3 = Arrays.<Class<? extends Reference>>asList(WeakReference.class);

may be the point in time when the compiler determines the new list's type: I figure it needs to determine the generic type of the list before considering the assignment. For this it takes the information it has to infer the type of the new list without regard to the assignment. This may cause two different types of list to be created by the two statements above, resulting in the observed behavior.

share|improve this answer
    
+1 I agree which is why I created the dummy MyList the way I did to restrict the intersection of types. –  Peter Lawrey Dec 30 '12 at 15:18

There are two parts to the explanation of this behavior:

  1. How does the type of the right-hand side change with changing arguments?
  2. Why are some of the RHS types incompatible with the LHS type?

1. The Right-Hand Side

The signature of asList is

<T> List<T> asList(T... a)

This means that all the arguments must be conflated into a single type T, which is the most specific type common to the types of all arguments. In this particular case, we have

asList(WeakReference.class) -> List<Class<WeakReference>>

and

asList(WeakReference.class, SoftReference.class) 
   -> List<Class<? extends Reference>>

Both of these are obvious enough.

2. The Left-Hand Side

Now, why can't we assign the first expression, of type List<Class<WeakReference>>, to a variable of type List<Class<? extends Reference>>? The best way to understand why the rules must be so is proof by contradiction. Consider the following:

  • List<Class<? extends Reference>> has add(Class<? extends Reference>)
  • List<Class<WeakReference>> has add(Class<WeakReference>).

Now, if Java allowed you to assign one to the other:

List<Class<WeakReference>> lw = new ArrayList<>();
List<Class<? extends Reference>> lq = lw;
lq.add(PhantomReference.class);

it would result in a clear violation of type safety.

share|improve this answer
    
You are changing the type of list2. ` List<Class<? extends Reference>> list2 = Arrays.asList(SoftReference.class); list.add(WeakReference.class); list.add(PhantomReference.class); ` –  Peter Lawrey Dec 30 '12 at 16:38
    
I have added an edit based on your example. I don't understand why it is an incompatible type. –  Peter Lawrey Dec 30 '12 at 16:43

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